Heat Conduction in Momentum-Conserving Fluids: From quasi-2D to 3D systems

Abstract

Using nonequilibrium and equilibrium molecular dynamics simulations, we investigate heat conduction in a momentum-conserving mesoscopic fluid modeled by multiparticle collision dynamics. Across quasi-two-dimensional (q-2D) to three-dimensional (3D) systems, we identify three distinct transport regimes: (i) a ballistic regime, where thermal conductivity scales linearly with system size ( L) and the total heat current autocorrelation function C(t) remains constant; (ii)~a kinetic regime, characterized by size-independent and exponentially decaying C(t), demonstrating that normal heat conduction dominated by kinetic effects is far more ubiquitous than previously observed in 1D systems; and (iii)~a hydrodynamic regime, where the q-2D system exhibits logarithmically divergent conductivity ( L ) with C(t) t-1 , while the 3D system displays finite and C(t) t-3/2 . Our results, observed in the hydrodynamic regime, quantitatively validate the scaling predictions for heat transport and reveal a clear dimensional crossover -- from 2D-like anomalous transport to 3D Fourier behavior. These results lay a foundation for understanding thermal transport in q-2D to 3D systems and have practical implications for the design of micro- and nanoscale thermal devices.